/* * This file is part of the flashrom project. * * Copyright (C) 2018 Miklós Márton martonmiklosqdev@gmail.com * * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation; either version 2 of the License, or * (at your option) any later version. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * */ /* The ni845x header does need the WIN32 symbol to be defined and meson does not do it. * Define it just here, since this driver will only work on 32-bit Windows. */ #ifndef WIN32 #define WIN32 #endif #include #include #include #include #include #include #include #include "flash.h" #include "programmer.h" #include "spi.h" #define NI845x_FIND_DEVICE_NO_DEVICE_FOUND -301701 enum USB845x_type { USB8451 = 0x7166, USB8452 = 0x7514, Unknown_NI845X_Device }; enum voltage_coerce_mode { USE_LOWER, USE_HIGHER }; struct ni845x_spi_data { unsigned char CS_number; // use chip select 0 as default enum USB845x_type device_pid; uInt32 device_handle; NiHandle configuration_handle; uint16_t io_voltage_in_mV; bool ignore_io_voltage_limits; }; // USB-8452 supported voltages, keep this array in ascending order! static const uint8_t usb8452_io_voltages_in_100mV[5] = { kNi845x12Volts, kNi845x15Volts, kNi845x18Volts, kNi845x25Volts, kNi845x33Volts }; /* Copied from dediprog.c */ /* Might be useful for other USB devices as well. static for now. */ static int parse_voltage(char *voltage) { char *tmp = NULL; int i; int millivolt = 0, fraction = 0; if (!voltage || !strlen(voltage)) { msg_perr("Empty voltage= specified.\n"); return -1; } millivolt = (int)strtol(voltage, &tmp, 0); voltage = tmp; /* Handle "," and "." as decimal point. Everything after it is assumed * to be in decimal notation. */ if ((*voltage == '.') || (*voltage == ',')) { voltage++; for (i = 0; i < 3; i++) { fraction *= 10; /* Don't advance if the current character is invalid, * but continue multiplying. */ if ((*voltage < '0') || (*voltage > '9')) continue; fraction += *voltage - '0'; voltage++; } /* Throw away remaining digits. */ voltage += strspn(voltage, "0123456789"); } /* The remaining string must be empty or "mV" or "V". */ tolower_string(voltage); /* No unit or "V". */ if ((*voltage == '\0') || !strncmp(voltage, "v", 1)) { millivolt *= 1000; millivolt += fraction; } else if (!strncmp(voltage, "mv", 2) || !strncmp(voltage, "millivolt", 9)) { /* No adjustment. fraction is discarded. */ } else { /* Garbage at the end of the string. */ msg_perr("Garbage voltage= specified.\n"); return -1; } return millivolt; } static void ni845x_report_error(const char *const func, const int32 err) { static char buf[1024]; ni845xStatusToString(err, sizeof(buf), buf); msg_perr("%s failed with: %s (%d)\n", func, buf, (int)err); } static void ni845x_report_warning(const char *const func, const int32 err) { static char buf[1024]; ni845xStatusToString(err, sizeof(buf), buf); msg_pwarn("%s failed with: %s (%d)\n", func, buf, (int)err); } /** * @brief ni845x_spi_open_resource * @param resource_handle the resource handle returned by the ni845xFindDevice or ni845xFindDeviceNext * @param opened_handle the opened handle from the ni845xOpen * @return the 0 on successful competition, negative error code on failure positive code on warning */ static int32 ni845x_spi_open_resource(char *resource_handle, uInt32 *opened_handle, enum USB845x_type pid) { // NI-845x driver loads the FPGA bitfile at the first time // which can take couple seconds if (pid == USB8452) msg_pwarn("Opening NI-8452, this might take a while for the first time\n"); int32 tmp = ni845xOpen(resource_handle, opened_handle); if (tmp < 0) ni845x_report_error("ni845xOpen", tmp); else if (tmp > 0) ni845x_report_warning("ni845xOpen", tmp); return tmp; } /** * @param serial a null terminated string containing the serial number of the specific device or NULL * @return the 0 on successful completion, negative error code on failure */ static int ni845x_spi_open(const char *serial, uInt32 *return_handle, enum USB845x_type *pid) { char resource_name[256]; NiHandle device_find_handle; uInt32 found_devices_count = 0; int32 tmp = 0; unsigned int vid, dev_pid, usb_bus; unsigned long int serial_as_number; int ret = -1; tmp = ni845xFindDevice(resource_name, &device_find_handle, &found_devices_count); if (tmp != 0) { // suppress warning if no device found if (tmp != NI845x_FIND_DEVICE_NO_DEVICE_FOUND) ni845x_report_error("ni845xFindDevice", tmp); return -1; } for (; found_devices_count; --found_devices_count) { // Read the serial number and the PID here // VISA resource name format example: // USB0::0x3923::0x7514::DEADBEEF::RAW // where the 0x7514 is the PID // and the DEADBEEF is the serial of the device if (sscanf(resource_name, "USB%u::0x%04X::0x%04X::%08lX::RAW", &usb_bus, &vid, &dev_pid, &serial_as_number) != 4) { // malformed resource string detected msg_pwarn("Warning: Unable to parse the %s NI-845x resource string.\n", resource_name); msg_pwarn("Please report a bug at flashrom@flashrom.org\n"); continue; } *pid = dev_pid; if (!serial || strtoul(serial, NULL, 16) == serial_as_number) break; if (found_devices_count > 1) { tmp = ni845xFindDeviceNext(device_find_handle, resource_name); if (tmp) { ni845x_report_error("ni845xFindDeviceNext", tmp); goto _close_ret; } } } if (found_devices_count) ret = ni845x_spi_open_resource(resource_name, return_handle, *pid); _close_ret: tmp = ni845xCloseFindDeviceHandle(device_find_handle); if (tmp) { ni845x_report_error("ni845xCloseFindDeviceHandle", tmp); return -1; } return ret; } /** * @brief usb8452_spi_set_io_voltage sets the IO voltage for the USB-8452 devices * @param requested_io_voltage_mV the desired IO voltage in mVolts * @param set_io_voltage_mV the IO voltage which was set in mVolts * @param coerce_mode if set to USE_LOWER the closest supported IO voltage which is lower or equal to * the requested_io_voltage_mV will be selected. Otherwise the next closest supported voltage will be chosen * which is higher or equal to the requested_io_voltage_mV. * @return 0 on success, negative on error, positive on warning */ static int usb8452_spi_set_io_voltage(uint16_t requested_io_voltage_mV, uint16_t *set_io_voltage_mV, enum voltage_coerce_mode coerce_mode, enum USB845x_type pid, uInt32 device_handle) { unsigned int i = 0; uint8_t selected_voltage_100mV = 0; uint8_t requested_io_voltage_100mV = 0; if (pid == USB8451) { *set_io_voltage_mV = 3300; msg_pwarn("USB-8451 does not support the changing of the SPI IO voltage\n"); return 0; } // limit the IO voltage to 3.3V if (requested_io_voltage_mV > 3300) { msg_pinfo("USB-8452 maximum IO voltage is 3.3V\n"); return -1; } requested_io_voltage_100mV = (requested_io_voltage_mV / 100.0f); // usb8452_io_voltages_in_100mV contains the supported voltage levels in increasing order for (i = (ARRAY_SIZE(usb8452_io_voltages_in_100mV) - 1); i > 0; --i) { if (requested_io_voltage_100mV >= usb8452_io_voltages_in_100mV[i]) break; } if (coerce_mode == USE_LOWER) { if (requested_io_voltage_100mV < usb8452_io_voltages_in_100mV[0]) { msg_perr("Unable to set the USB-8452 IO voltage below %.1fV " "(the minimum supported IO voltage is %.1fV)\n", (float)requested_io_voltage_100mV / 10.0f, (float)usb8452_io_voltages_in_100mV[0] / 10.0f); return -1; } selected_voltage_100mV = usb8452_io_voltages_in_100mV[i]; } else { if (i == ARRAY_SIZE(usb8452_io_voltages_in_100mV) - 1) selected_voltage_100mV = usb8452_io_voltages_in_100mV[i]; else selected_voltage_100mV = usb8452_io_voltages_in_100mV[i + 1]; } if (requested_io_voltage_100mV < usb8452_io_voltages_in_100mV[0]) { /* unsupported / would have to round up */ msg_pwarn("The USB-8452 does not support the %.1fV IO voltage\n", requested_io_voltage_mV / 1000.0f); selected_voltage_100mV = kNi845x12Volts; msg_pwarn("The output voltage is set to 1.2V (this is the lowest voltage)\n"); msg_pwarn("Supported IO voltages:\n"); for (i = 0; i < ARRAY_SIZE(usb8452_io_voltages_in_100mV); i++) { msg_pwarn("%.1fV", (float)usb8452_io_voltages_in_100mV[i] / 10.0f); if (i != ARRAY_SIZE(usb8452_io_voltages_in_100mV) - 1) msg_pwarn(", "); } msg_pwarn("\n"); } else if (selected_voltage_100mV != requested_io_voltage_100mV) { /* we rounded down/up */ msg_pwarn("USB-8452 IO voltage forced to: %.1f V\n", (float)selected_voltage_100mV / 10.0f); } else { /* exact match */ msg_pinfo("USB-8452 IO voltage set to: %.1f V\n", (float)selected_voltage_100mV / 10.0f); } if (set_io_voltage_mV) *set_io_voltage_mV = (selected_voltage_100mV * 100); i = ni845xSetIoVoltageLevel(device_handle, selected_voltage_100mV); if (i != 0) { ni845x_report_error("ni845xSetIoVoltageLevel", i); return -1; } return 0; } /** * @brief ni845x_spi_set_speed sets the SPI SCK speed * @param SCK_freq_in_KHz SCK speed in KHz * @return */ static int ni845x_spi_set_speed(NiHandle configuration_handle, uint16_t SCK_freq_in_KHz) { int32 i = ni845xSpiConfigurationSetClockRate(configuration_handle, SCK_freq_in_KHz); uInt16 clock_freq_read_KHz; if (i != 0) { ni845x_report_error("ni845xSpiConfigurationSetClockRate", i); return -1; } // read back the clock frequency and notify the user if it is not the same as it was requested i = ni845xSpiConfigurationGetClockRate(configuration_handle, &clock_freq_read_KHz); if (i != 0) { ni845x_report_error("ni845xSpiConfigurationGetClockRate", i); return -1; } if (clock_freq_read_KHz != SCK_freq_in_KHz) { msg_pinfo("SPI clock frequency forced to: %d KHz (requested: %d KHz)\n", (int)clock_freq_read_KHz, (int)SCK_freq_in_KHz); } else { msg_pinfo("SPI clock frequency set to: %d KHz\n", (int)SCK_freq_in_KHz); } return 0; } /** * @brief ni845x_spi_print_available_devices prints a list of the available devices */ static void ni845x_spi_print_available_devices(void) { char resource_handle[256], device_type_string[16]; NiHandle device_find_handle; uInt32 found_devices_count = 0; int32 tmp = 0; unsigned int pid, vid, usb_bus; unsigned long int serial_as_number; tmp = ni845xFindDevice(resource_handle, &device_find_handle, &found_devices_count); if (tmp != 0) { // suppress warning if no device found if (tmp != NI845x_FIND_DEVICE_NO_DEVICE_FOUND) ni845x_report_error("ni845xFindDevice", tmp); return; } if (found_devices_count) { msg_pinfo("Available devices:\n"); do { tmp = sscanf(resource_handle, "USB%d::0x%04X::0x%04X::%08lX::RAW", &usb_bus, &vid, &pid, &serial_as_number); if (tmp == 4) { switch (pid) { case USB8451: snprintf(device_type_string, ARRAY_SIZE(device_type_string), "USB-8451"); break; case USB8452: snprintf(device_type_string, ARRAY_SIZE(device_type_string), "USB-8452"); break; default: snprintf(device_type_string, ARRAY_SIZE(device_type_string), "Unknown device"); break; } msg_pinfo("- %lX (%s)\n", serial_as_number, device_type_string); found_devices_count--; if (found_devices_count) { tmp = ni845xFindDeviceNext(device_find_handle, resource_handle); if (tmp) ni845x_report_error("ni845xFindDeviceNext", tmp); } } } while (found_devices_count); } tmp = ni845xCloseFindDeviceHandle(device_find_handle); if (tmp) ni845x_report_error("ni845xCloseFindDeviceHandle", tmp); } static int ni845x_spi_shutdown(void *data) { struct ni845x_spi_data *ni_data = data; int32 ret = 0; if (ni_data->configuration_handle != 0) { ret = ni845xSpiConfigurationClose(ni_data->configuration_handle); if (ret) ni845x_report_error("ni845xSpiConfigurationClose", ret); } if (ni_data->device_handle != 0) { ret = ni845xClose(ni_data->device_handle); if (ret) ni845x_report_error("ni845xClose", ret); } free(data); return ret; } static void ni845x_warn_over_max_voltage(const struct flashctx *flash) { const struct ni845x_spi_data *data = flash->mst->spi.data; if (data->device_pid == USB8451) { msg_pwarn("The %s chip maximum voltage is %.1fV, while the USB-8451 " "IO voltage levels are 3.3V.\n" "Ignoring this because ignore_io_voltage_limits parameter is set.\n", flash->chip->name, flash->chip->voltage.max / 1000.0f); } else if (data->device_pid == USB8452) { msg_pwarn("The %s chip maximum voltage is %.1fV, while the USB-8452 " "IO voltage is set to %.1fV.\n" "Ignoring this because ignore_io_voltage_limits parameter is set.\n", flash->chip->name, flash->chip->voltage.max / 1000.0f, data->io_voltage_in_mV / 1000.0f); } } static int ni845x_spi_io_voltage_check(const struct flashctx *flash) { struct ni845x_spi_data *data = flash->mst->spi.data; static bool first_transmit = true; if (first_transmit && flash->chip) { first_transmit = false; if (data->io_voltage_in_mV > flash->chip->voltage.max) { if (data->ignore_io_voltage_limits) { ni845x_warn_over_max_voltage(flash); return 0; } if (data->device_pid == USB8451) { msg_perr("The %s chip maximum voltage is %.1fV, while the USB-8451 " "IO voltage levels are 3.3V.\nAborting operations\n", flash->chip->name, flash->chip->voltage.max / 1000.0f); return -1; } else if (data->device_pid == USB8452) { msg_perr("Lowering IO voltage because the %s chip maximum voltage is %.1fV, " "(%.1fV was set)\n", flash->chip->name, flash->chip->voltage.max / 1000.0f, data->io_voltage_in_mV / 1000.0f); if (usb8452_spi_set_io_voltage(flash->chip->voltage.max, &data->io_voltage_in_mV, USE_LOWER, data->device_pid, data->device_handle)) { msg_perr("Unable to lower the IO voltage below " "the chip's maximum voltage\n"); return -1; } } } else if (data->io_voltage_in_mV < flash->chip->voltage.min) { if (data->device_pid == USB8451) { msg_pwarn("Flash operations might be unreliable, because the %s chip's " "minimum voltage is %.1fV, while the USB-8451's " "IO voltage levels are 3.3V.\n", flash->chip->name, flash->chip->voltage.min / 1000.0f); return data->ignore_io_voltage_limits ? 0 : -1; } else if (data->device_pid == USB8452) { msg_pwarn("Raising the IO voltage because the %s chip's " "minimum voltage is %.1fV, " "(%.1fV was set)\n", flash->chip->name, flash->chip->voltage.min / 1000.0f, data->io_voltage_in_mV / 1000.0f); if (usb8452_spi_set_io_voltage(flash->chip->voltage.min, &data->io_voltage_in_mV, USE_HIGHER, data->device_pid, data->device_handle)) { msg_pwarn("Unable to raise the IO voltage above the chip's " "minimum voltage\n" "Flash operations might be unreliable.\n"); return data->ignore_io_voltage_limits ? 0 : -1; } } } } return 0; } static int ni845x_spi_transmit(const struct flashctx *flash, unsigned int write_cnt, unsigned int read_cnt, const unsigned char *write_arr, unsigned char *read_arr) { const struct ni845x_spi_data *data = flash->mst->spi.data; uInt32 read_size = 0; uInt8 *transfer_buffer = NULL; int32 ret = 0; if (ni845x_spi_io_voltage_check(flash)) return -1; transfer_buffer = calloc(write_cnt + read_cnt, sizeof(uInt8)); if (transfer_buffer == NULL) { msg_gerr("Memory allocation failed!\n"); return -1; } memcpy(transfer_buffer, write_arr, write_cnt); ret = ni845xSpiWriteRead(data->device_handle, data->configuration_handle, (write_cnt + read_cnt), transfer_buffer, &read_size, transfer_buffer); if (ret < 0) { // Negative specifies an error, meaning the function did not perform the expected behavior. ni845x_report_error("ni845xSpiWriteRead", ret); free(transfer_buffer); return -1; } else if (ret > 0) { // Positive specifies a warning, meaning the function performed as expected, // but a condition arose that might require attention. ni845x_report_warning("ni845xSpiWriteRead", ret); } if (read_cnt != 0 && read_arr != NULL) { if ((read_cnt + write_cnt) != read_size) { msg_perr("%s: expected and returned read count mismatch: %u expected, %ld received\n", __func__, read_cnt, read_size); free(transfer_buffer); return -1; } memcpy(read_arr, &transfer_buffer[write_cnt], read_cnt); } free(transfer_buffer); return 0; } static const struct spi_master spi_programmer_ni845x = { .max_data_read = MAX_DATA_READ_UNLIMITED, .max_data_write = MAX_DATA_WRITE_UNLIMITED, .command = ni845x_spi_transmit, .read = default_spi_read, .write_256 = default_spi_write_256, .shutdown = ni845x_spi_shutdown, }; static int ni845x_spi_init(const struct programmer_cfg *cfg) { char *speed_str = NULL; char *CS_str = NULL; char *voltage = NULL; char *endptr = NULL; int requested_io_voltage_mV = 1200; // default the IO voltage to 1.2V int spi_speed_KHz = 1000; // selecting 1 MHz SCK is a good bet char *serial_number = NULL; // by default open the first connected device char *ignore_io_voltage_limits_str = NULL; bool ignore_io_voltage_limits; unsigned char CS_number = 0; enum USB845x_type device_pid = Unknown_NI845X_Device; uInt32 device_handle; int32 tmp = 0; // read the cs parameter (which Chip select should we use) CS_str = extract_programmer_param_str(cfg, "cs"); if (CS_str) { CS_number = strtoul(CS_str, NULL, 10); free(CS_str); if (CS_number > 7) { msg_perr("Only CS 0-7 supported\n"); return 1; } } voltage = extract_programmer_param_str(cfg, "voltage"); if (voltage != NULL) { requested_io_voltage_mV = parse_voltage(voltage); free(voltage); if (requested_io_voltage_mV < 0) return 1; } serial_number = extract_programmer_param_str(cfg, "serial"); speed_str = extract_programmer_param_str(cfg, "spispeed"); if (speed_str) { spi_speed_KHz = strtoul(speed_str, &endptr, 0); if (*endptr) { msg_perr("The spispeed parameter passed with invalid format: %s\n", speed_str); msg_perr("Please pass the parameter with a simple number in kHz\n"); return 1; } free(speed_str); } ignore_io_voltage_limits = false; ignore_io_voltage_limits_str = extract_programmer_param_str(cfg, "ignore_io_voltage_limits"); if (ignore_io_voltage_limits_str && strcmp(ignore_io_voltage_limits_str, "yes") == 0) { ignore_io_voltage_limits = true; } if (ni845x_spi_open(serial_number, &device_handle, &device_pid)) { if (serial_number) { msg_pinfo("Could not find any connected NI USB-8451/8452 with serialnumber: %s!\n", serial_number); ni845x_spi_print_available_devices(); msg_pinfo("Check the S/N field on the bottom of the device,\n" "or use 'lsusb -v -d 3923:7166 | grep Serial' for USB-8451\n" "or 'lsusb -v -d 3923:7514 | grep Serial' for USB-8452\n"); free(serial_number); } else { msg_pinfo("Could not find any connected NI USB-845x device!\n"); } return 1; } free(serial_number); struct ni845x_spi_data *data = calloc(1, sizeof(*data)); if (!data) { msg_perr("Unable to allocate space for SPI master data\n"); return 1; } data->CS_number = CS_number; data->device_pid = device_pid; data->device_handle = device_handle; data->ignore_io_voltage_limits = ignore_io_voltage_limits; // open the SPI config handle tmp = ni845xSpiConfigurationOpen(&data->configuration_handle); if (tmp != 0) { ni845x_report_error("ni845xSpiConfigurationOpen", tmp); goto err; } if (usb8452_spi_set_io_voltage(requested_io_voltage_mV, &data->io_voltage_in_mV, USE_LOWER, data->device_pid, data->device_handle) < 0) { // no alert here usb8452_spi_set_io_voltage already printed that goto err; } if (ni845x_spi_set_speed(data->configuration_handle, spi_speed_KHz)) { msg_perr("Unable to set SPI speed\n"); goto err; } return register_spi_master(&spi_programmer_ni845x, data); err: ni845x_spi_shutdown(data); return 1; } const struct programmer_entry programmer_ni845x_spi = { .name = "ni845x_spi", .type = OTHER, // choose other because NI-845x uses own USB implementation .devs.note = "National Instruments USB-845x\n", .init = ni845x_spi_init, };